Furnace reactor



June 17, 1952 v. F. PARRY FURNACE-REACT0R 12 sheets-sheet 1 original Filed April 2o, i345v Ydvll 00 .0 I

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V. F. PARRY FURNACE REACTOR June 17, 1952 '12 sheets-sheet 2 Original Filed April 20,

P4 MT5@ M um# W Jane 17, 1952 v. F. PARRY FURNACE REACTOR Original Filed April 20, 1945 1 A 8 2 n m a .m 9 5 H M E l. f r .l 5 .H .M um d SMN@ M65 2" M 4 M IN V EN TOR.

F m n m J'une 17, 1952 v. F. PARRY 2,6005425.

FURNACE REACTOR Original Filed April 20', 1945 12 Sheecs-Sheerl 4 INVENToR. l/@VHOH rn c/A June 17, 1952 v. F. PARRY v FuRNAcE-REACTOR 12 sheets-sheet 5 Original Filed April 20, 1945 Cgi INVENTOR.

Vernon F 79"7 June 17, 1 952 v.-F. PARRY 2,600,425

FURNACE REACTOR Original Filed April 20, :.945 l2 Sheets-Sheet 7 l INVENTOR. Verna" fly Amm l2 Sheets-Sheet 8 Original Filed April 20, 1945 INVENTOR.

m om June 17, 1952 v. F. PARRY FURNACE 'REACTOR l2 Sheets-Sheet 9 Original Filed April 20, 1945 V. F. PARRY FURNACE REACTOR June 17, 1952 l2 Sheets-Sheet l0 Original Filed April 20, 1945 INVENTOR. Vernon F/ga/rr/ FIG. I4

June 17, 1952 v v. F. PARRY 2,600,425

FURNACE REACTOR Original Filed April 20, 1945 12 Sheets-Sheet 11 NVENTOR. Vernon T Hrr/ June 17, .1952 v. F. PARRY 2,600,425

FURNACE REACTOR FIG. I6.

INVENTOR. y l/ernn P 734/7/ Patented June 17, 1952 FURNACE` REACTOR Vernon F. Parry, Golden, Colo., assignor to Silver Engineering Works, Inc., Denver, Colo., a corporation of Colorado Original application April 20, 1945, Serial No. 589,450. Divided and this application- October 7, 1946, Serial No. 701,631

(Cl. .Z3-277) (Granted under the act of March 3, 1883, as amended April 30, 1928; 370 0. G. 757) 7 Claims.

The invention described herein may be manufactured and used by or for the Government of the United States for governmental purposes without the payment to me of any royalty thereon in accordance with the provisions of the act of April 30, 1928 (Ch. 460, 45 Stat. L. 467).

This invention relates to chemical reaction apparatus and methods, and more particularly to suitable methods and devices for carrying out endothermic chemical reactions involving solid and gaseous or vaporous materials, Still more particularly, this invention relates to processes for the production of synthesis gas and fuel gas from subbituminous coal or other non-caking or non-agglomerating carbonaceous materials in a vertically ranging externally heated annular retort.

Heretofore in the fuel converting art large reaction vessels requiring heat transfer at high temperatures, have been made of refractory fire brick and heated by gas or oil-fired ovens. Such refractory fire-brick settings have low thermal conductivity and they transmit heat relatively slowly compared with the heat transfer which may be transmitted through metals. In the heating of metallic reaction vessels, troubles are usually encountered from local overheating which causes excessive corrosion, unequal expansion, and short useful life of the metal. It has now been found that by employing the special heating system herein described, alloy reaction vessels can be heated safely and uniformly in controlled atmosphere, and their useful life extended through a long period of continuous operation.

Heretofore, in the production of water gas, synthesis gas, and the like, it has been necessary to employ batch operation, alternately to blow steam through the incandescent fuel bed to yield such gas. It is not feasible to use low rank fuels such as lignite or subbituminous coal in machines employing intermittent alternating blasts of air and steam, because of decrepitation of the fuel under such treatment which causes excessive back pressure and abnormal losses in the form of ne dust. Therefore the low-rank fuels have not been used for making water gas, but it has now been found that in accordance with this invention, lignite, subbituminous coal, or other non-coking fuels can be gasified successfully, and

the desired water gas reactions, as well as other chemical endothermic reactions involving solids and gaseous materials, can be carried out in a continuous manner at higher efficiencies than can be obtained by other processes.

In the United States the principal raw materials now used for manufacture of water gas are the higher rank bituminous coals used either in their natural state or converted to hard coke by well known carbonization processes. These fuels are not reactive and high temperatures are necessary when gasifying them by reaction with steam or other gases. It is not feasible to conduct the so called water gas reactions on high rank fuels in metal vessels because of rapid deterioration of the vessels caused by the high temperature of the reaction. On the other hand the low-rank fuels, such as subbituminous coal and lignite, have relatively high reactivity, endowed by nature, which permits the various water gas reactions to be conducted at relatively low temperatures within a range permitting use of alloy steel reaction vessels. For example the high rank fuels must be heated to temperatures in excess of 1800 degrees F. in order to make water gas by reaction with steam, but the low rank fuels start to react with water at temperatures as low as 1200 degrees F., and in the temperature range 1550 to 1850 degrees F. the rate of reaction is very fast, in fact fast enough to justify commercial operation. Thus it is feasible to make industrial water gas from low-rank fuels in externally heated metallic retorts because of the natural property of high reactivity possessed by these fuels, and this invention is designed to take advantage of that property.

This invention accordingly has for its object the provision of a method and apparatus for continuously carrying out endothermic chemical reactions involving a solid material having gas forming and liqueliable constituents and a gaseous substance. Another object is to provide a suitable method and apparatus for the continuous production of synthesis gas from lignite or other non-caking carbonaceous material. Another object is the continuous production of a gas containing a controlled ratio of hydrogen to carbon monoxide from non-caking carbonaceous materials, While producing a maximum quantity of condensible oil or tar from the carbonaceous materials with gasification of the carbon residue. Further objects relate to the production of relatively smokeless fuels from non-caking coals; to the reduction of metallic ores such as those of iron, magnesium, zinc, and similar ores; and to suitable apparatus for carrying out the foregoing reactions and reductions. An important object of the invention is the provision of a suitable combustion system, which employs improved means of recuperation, for heating the vertically ranging externally heated retort, and an improved air-cooled fan for recirculation of products of combustion. This heating system makes it possible to conduct the several processes described herein at maximum thermal efiiciency. Other objects of the invention will be apparent or will appear as the ensuing description proceeds.

In accordance with this invention an endothermio chemical reaction process involving va solid material and a gaseous or vaporous substance is carried out by passing said .material through a stage heated annular reaction Zone Vwhile withdrawing gaseous reactionproductsirom a heat exchange zone enveloped by said reaction zone. It has been found that stage heated annular reaction zones provide superior means for carrying out endothermic chemical-reactions between solids and gases of vapors, since heat can be supplied to the reactants with veryrhigh emciency in heat resisting metallic vessels, and by utilizing the interior of an annular reaction-zone as a heat exchange zone for withdrawing gaseous or vaporous products, increased efficiency can be tobtained.

'This invention also :contemplates carrying l out Aanfendothermic chemical'reaction involvingrgaseous and 'solid ,materials :by .passing said :materials concurrently downward through 'an Vexternally-heated verticallyranging elongated annular reactionV zone, withdrawing gaseous `products Sfrom said reactionzone nearthezoneof maximumzreaction temperature and discharging said igaseous products upwardly -while maintaining `them in indirect heat exchange relation yto said descending reactants, ythen discharging 'spent 'solids from a lower-annular reaction zone-coun- `ter-currently to ascending ga-ses, while maintaining said lower annular reaction zone in in- Adirect Iheat exchange relation with `incoming lgaseous or vaporous reactants. By providingltwo vannular reaction zones as described, Athe-entering slid and gaseous m-aterials are preheated =while :recovering heat `from exhausted gaseous prod- --ucts, and atterattaining a maximum reaction temper-ature, the solid reactants -are `further passed in heat exchange vrelation to additional incoming gaseous or vaporous reactants-or oar- `rior-gases as the casemay be.

Thisfinvention'also comprises suitable apparatus `for Acarrying out endothermic chemicalreacftions comprising an elongated vvertically ranging vessel having means 'for heating the 'same and a-heat exchange device within said vessel denn- `ing 'therewith an annular reaction zone,'said devicefhaving an Vopening therein communicating with said annular reaction zone for withdraw'- VVing gaseous vproducts of reaction from said zone.

In -the following description, `it should be understood that the 'term gaseous includes materials which are vapors at the temperatures encountered, such asforiexample, steam, oil vapors, 4and similar materials. lFurthermore the terms `non-caking, non-,agglomerating or non-coking `are Vassociated with and define a material Vthat 'does not swell or fuse to destroy 'its ability to `move 4by gravity asa relatively free-owing ma- -terial. In describing the apparatus and method of this inventioruthe description will be directed principally to the gasincation of 'lignite ,or sub- `Abituminous coal, but the invention is not'limited `thereto-as will be apparent.

The reader will .appreciatethe improvement in the art and eiciency of gasification of fuel made possible by this invention when he considers the brief comparison cited herewith:

'Inpresent commercial processes for the-manufacture ofsynthesis .gas .from coke, as practiced ,hy .large War II industries, one ton of ,high-rank .about 35,000 4cubic feet of zsynthesis fgas.

bituminous coking coal of 13,500 B. t. u. per pound, after coking in a coke oven, will make The conversion reguires 2 steps; o. Coking in the coke oven by intermittent operation; and, b.

:,Gasication in a water gas machine by intermittent blasting with air and steam. In the conltinuous process comprising this invention one ton of Anatur-a1 subloituminous coal containing about '22 percent water and having a heating `value-of 'only 9,-300.B t. u. per pound, is gasied been invented.

In the accompanying drawings:

Figure l is a-viewpartly in sectionandpartly A'dia'grammati'c showing a vertically 4ranging Iannuar Ireaction lapparatus having an external heating chamber and a recuperator associated therewith.

Figure V2 isa View, partly in section and partly diagrammatic, showing a vertically ranging annular reaction apparatus similar to Figure Land showing also a-suitable'arrangement forffeeding incoming solids; removing, cooling, and scrubbing evolved gases and vapors; and recycling productsof combustion.

Figure 3 is a'view, partly-in seotion'andipartly diagrammatic, showing a generating unit and the recycling "apparatus-of A-Figure 2 on'asom'ewhat enlarged scale.

Figure 4 isa view, partly in section and partly diagrammatic uf 'the device of Figures 4l and 2 suitably modied by the addition of heat exchange means for .imparting Vheat to incoming solids vfrom the spent vproducts of combustion, and .also providing a diiierent `arrangement 'of annular domes in the reaction zoneparticularly 4adapted to the production o'foil and 'fixed gases from voil-.bearing shales, or .low-.temperature ytar and xed gases .from-non-.coking coals wherein secondary decomposition of fdistillation `.products is repressed. The figure also shows'anarrange- Ament of a bubble-tower for fractional condensation of vapors.

lFigure 5 is 'anenlarged sectional view, lpartly diagrammatic, wherein 'the Y'central reaction van- .nulus of :Figures 1,12, A3 and 4 is formed from a plurality of segmentaloverlapping annuli'to accommodate removal ofvapors.

Figure 6 is an enlarged view, partly diagrammatic, Aof'an alternative arrangement for the central annulus of the apparatus `shown in Figures '1, 2, 3 and 4, wherein the annulus has a series `of slotted orices for venting evolved gases assisted by the Venturi' effect.

Figure 6a is a detailed section of optional orices in the inner cylindrical annulus of Figure 6.

Figure l'is an enlarged sectional View of a further alternative arrangement for Athe annular reaction apparatus of Figures 12, 3 and .4 provided with a supplementary heat exchanger vin the central portion of the upperheat exchange zone whereby gases admitted to the lower heat exchange zone take up heat `from the .gaseous products of reaction.

Figure 8 is an enlarged View, partly insection and partly diagrammatic, of the annular portion Qi the apparatus of Figure 4 providing means for recirculating a portion of the Xed gases to the lower annulus.

Figure 9 is an enlarged detailed sectional view, partly diagrammatic, showing a modification of the superposed annular reaction apparatus of Figure 7 adapted to the successive distillation of volatiles and gasification of residual carbon in non-agglomerating carbonaceous materials, such as lignite, subbituminous coal, and oil shales.

Figure 10 is an enlarged sectional view, partly diagrammatic, showing the annular reaction device of Figure 3 having a suitable arrangement for introducing gas-oil or carburetting oil to both annular zones whereby carburetted water gas can be made continuously.

Figure 11 is a sectional view, partly diagrammatic, showing the addition of a second inner elongated annulus to the apparatus of Figures 1 and 3 whereby the apparatus becomes well suited for the reduction of granular iron ore.

Figure 11a, is an enlarged View taken on the line B-B of Figure 1l, showing the construction of optional vents for transferring gas from the inner to the outer annular zone.

Figure l2 is a sectional view, partly diagrammatic, of the lower part of the annular reaction vessel and furnace of Figures 2 and 3 showing a suitable mechanical scraper for removing spent material from the lower annulus, and a transfer screw to move the material into a gas producer.

Means for directing hot gas through a dust catcher and to the burner manifold are indicated. Figure 12 also shows a preheater inside the combustion chamber for preheating steam or xed gases introduced into the lower annulus.

Figure 12a is a detailed section of the inlet pipe to the lower reaction Zone showing a packing gland and collar.

Figure 13 is a sectional View, partly diagrammatic, of the lower part of the annular vreaction vessel and furnace of Figure 4 having a central draft inlet for introduction of air and steam to gasify xed carbon and volatile matter in spent shale or earbonaceous material discharged from the heated reaction annulus, a transfer screw to remove spent material and means for cooling the outgoing solids.

Figure 13a is an enlarged view of the central draft inlet showing an arrangement of ports and conical baflles providing for introduction of a gaseous reactant.

Figure 14 shows sectional views of the brickwork, gas firing ports, air ducts, and combustion chamber surrounding the annular vessel of Figures l, 2 and 3. In Figure 14a the section is drawn horizontally across the vessel at points C-C referred to in Figure l. Figure 14h shows a section through DD and Figure 14e is a section through EE of Figure 1.

Figure 15 is a sectional view, partly diagrammatic showing the apparatus suitably modified to provide for the continuous reduction of metallic ores wherein the reduced metal is vaporizable at the temperature of reduction and is recoverable through a suitable internal condenser.

Figure 16 is a view, partly in section and partly diagrammatic, showing an optional arrangement of the combustion system involving direct recirculation of products of combustion.

Figure 16a is an enlarged View. partly in section and partly diagrammatic, showing the gas duct and air-cooled fan assembly of Figure 16.

Figure 16h is an enlarged diagrammatic view of the air-cooled fan.

The following brief description explains a lprocedure for making gas from un-dried subbitumi'- nous coal by the method outlined in this invention. Referring to Figure 3, freshly mined subbituminous coal containing about 22 percent moisture is charged into the top of the apparatus and directed downwardly by gravity through annular preheating and reaction zones. Steam is mixed with the coal and reaction begins as the temperature increases. The products of reaction are removed from the interior of the annular reaction Zone and give up a substantial portion of their sensible heat to incoming reactants. Solid materials not combined with reactants in the upper zone are then directed downwardly where they contact cooling gases which transfer heat from the solids back toward the center of the system, and the spent solids are discarded at a low temperature. Thus, heat for carrying out the gasification reactions is retained near the center of the system, and products leave at low temperature which insures high eiciency. In

gasifying un-dried subbituminous coal, up to 95,000 gross-cubic feet of water gas is obtained per ton of coal treated. The spent residue contains only 2 to 10 percent of the carbon originally present in the raw coal charged. Part of the gas made may be chrected back for heating the reaction vessel or suitable producer gas may be generated from spent solids to supply heat for the reactions. The combustion system is arranged to return heat to the high-temperature zone and to recover substantially all the heat from the evolved gases.

For a practical embodiment of the invention, and referring now to the drawings, an elongated vessel 58 which may be vertically mounted as shown, is provided near its upper end with a suitable device for feeding solid materials later to be described, and is closed at its lower end by a suitable closure device forming a part of the supporting means for the vessel 55. As shown in Figures 1, 2, 3 and 4, the closure device is an inverted conical annulus or a flat circular cup as shown in Figure l2. The vessel 58 may have any desired cross-sectional form, but it is preferably made circular in order to simplify construction. Connecting the conical discharge annulus I 30 and the vessel 55 is an expansion joint seal 55, which may be of the flanged or ring type. The conical annulus |30 or flat circular cup 14 is supported by suitable adjustable resilient mount's l' 49 or 49a which may take the form of springs or hydraulic jacks (not shown) adapted to exert an upward pressure against the force of gravity and to maintain any desired stress condition in the vessel 56.

Connected to the conical annulus H30 is a device for discharging spent solid material While maintaining a gas-tight seal. As shown in Figure 4, the device comprises a pair of oppositely rotating serrated cylinders or star feed- `ers 4S. Below the cylinders 48 is a butterfly valve ISI for causing solids to be vented into a waterseal ITG. The seal HS is provided with a, drag conveyor 50a. Alternatively, the discharging device as shown in Figure 2 may take the form of a rotarykvapor sealing valve 48a of the paddle wheel type in conjunction with a water-filled screw conveyor 50. A further modification of the discharging device, shown in Figure 12, may take the form of a flat circular cup 'M supporting the vessel 55 having a revolving curved paddle scraper 53 to take solids from the periphery and to discharge them through the central duct 6l where they are fed to a screw conveyor 50 communicating with a gas producer 59. The hot carbonaceous solids are cooled by introduction f a cooling gas or liquid through cooling ports 'lil in the conveyor 5U. When water is used vfor cooling, an eliective gas seal for moderate pressures is obtained between 'the vessel 56 .and the gas producer S. In operating this form of discharge, the scraper B3 is turned by vertical shaft 58 and pinion 3S, which may operate at variable speed to adjust the rate of discharge suitably correlated with the driving pulley .S8 lforthe conveyor 5B. A further modification of the discharge device, shown in Figure 13, may take the form of a sloping screw conveyor 53 driven by a variable speed motor (not shown) attached to drive pulley 88. Dry material can be removed by this device at constant rate depending upon the speed of the screw 55 conveyor. Sealing is accomplished by introduction of cooling `water in ports 13. vThe packing gland l1 which is similar to that shown in Figure 12a, can be adjusted to compensate for expansion of vessel 56. A further modication of the discharging device, shown in Figure l5, may take the form of a hold-up receiver 93 provided with a suitable 'inlet vapor sealing valve 92 communicating with the vessel 5S and an outlet vapor sealing valve 94 discharging the contents of the hold-up receiver 93. For operation at a pressure substantially diiierent from atmospheric, the receiver 93 is provided with a. pressure-equalizing valve |3. In operating this form of discharging device, the valve 32 is opened while valves H3 `and '94 are closed, and a portion of the contents of the vessel 5G are allowed to enter the receiver S3. lTher.,- upon valve 32 is closed, venting `valve H3 is opened, and discharge valve Sil is opened.

For the purpose of deiining an annular reaction Zone while removing the formed gaseous products with concurrent internal heat exchange, there is aligned within the elongated vessel 55 a suitable heat exchange device 5B dening with the vessel 56 an annular reaction zone 33. As shown in Figure 6, such a device is an elongated cylindrical annulus 58, spaced away from and aligned with vessel A56 or an elongated annulus, as shown in Figure l5,-of reduced diameter at its lower end. In either case the annulus 58 is open at its lower end, and extends substantially the entire length of the vessel 55. Located within the reaction zone 33 are positioned a plurality of spaced temperature-responsive elements 9, il, |I, and M for indicating temperatures on recording devices (not shown). and to aid in controlling reactions later to be described. Preferably, the temperature responsive elements 9, lll, and le are supported on the heat ex- Change device 58. Surmounting the upper portion of the cylindrical annulus 58 is a vent pipe 5| for removing gaseous products from the heat exchange zone lll within the cylindrical annulus 58.

Suitable means are provided for conducting evolved gases from the reaction zone 33 into the heat exchange zone dil, being shown in Figure 6a as a. plurality of circumferentially-spaced louvers |29 in the cylindricalannulus 58. Alternatively, the gas-conducting means may take the form of a plurality of slots 63 as shown in Figure 6.

Optionally, as shown in Figure 5, the cylindrical annulus 5S may he formed of a plurality of spaced overlapping frustro-conical annuli |32, whereby gas passes between the annuli |32. This form of the annulus 58 provides for removal of reaction gas throughout the entire length of the reaction zone 33, .thus minimizing undesired decomposition.

.For the treatment of solids which tend to swell or do not shrink substantially during treatment, the cylindrical annulus 58 is preferably made progressively smaller in diameter toward its lower portion, as shown in Figure 15, thus making the annular space 33 of increasing width progressively toward the bottom in order to facilitate free gravitational flow of solids downwardly through the reaction zone 33.

Suitable means for feeding solid materials, alone or admixed with liquid or gaseous substances, are provided near the upper end of the vessel 56. As shown in Figure 2, such means may comprise a conveyor or skip hoist (not shown) leading to a hopper 33. From the hopper 30 the solid feed material passes downwardly by gravity through vapor sealing cone valves 3| into a preheating zone 30 in the vessel 56 as shown in Figures 2, 3 and 4. The cone valves 3| are actuated by means of suitable wheels 32. Other suitable means for introducing solids continuously into the top preheating Zone 88 may be used. Gptionally, as Shown in Figure l5, for operation at a pressure substantially dierent from atmospheric, pressure retaining valves i8 and 19 may be employed for admitting materials from the hopper 30 to the interior of the vessel 56.

Upon entering the vessel 56 a relatively large body of-incoming solid materials is held up in the preheating zone 8|! deiined by the vessel 55 and the vent pipe Lil, whereby heat is taken up by the solids from the evolved gases passing in indirect countercurrent heat exchange relationship to the solids.

If desired, suitable means are provided for admitting gaseous or vaporous materials to thepreheating zone in the upper portionof the vessel 56. As shown in Figures 2 and 3 an inlet pipe 38 is connected to an annular jacket 39 positioned in the heat exchange zone Be surrounding the vent pipe lll whereby the hot gases issuing through the vent pipe 4| serve to pre-heat the incoming vapors. The jacket 39 is provided'with suitable openings near the lower Aportion 'thereof or is merely left open at the bottom, as shown, so that steam or other gaseous reactant -is admixed in the preheating zone 83 with the solid materials. The preheating zone 80 is suitablylagged or otherwise insulated against heat losses by a heat 'insulating layer |33.

For many chemical reactions involving solid and gaseous or vaporous reactants, it has been found that a plurality of internal'heat exchange devices mounted in the common elongated vessel 5S provides a superior annular reaction apparatus, particularly where it is desired to carry out a multiple-stage reaction involving concurrent treatment of solids and gases in a iirst annular reaction zone and countercurrent treatment of solids Vand gases in a second annular reaction zone. A suitable form of apparatus particularly shown'in vFigures 1, 2, 3 and 4, comprises a cylindrical annulus 58 occupying the upper portion of the elongated vessel 56 aligned therein and surmounting, but spaced from a lower cylindrical annulus 35. As shown, the lower cylindrical annulus 36 is capped by a conical closure |34. The wall of the lower cylindrical annulus 3G defines with the wall of the elongated vessel 56 a second or lower reaction zone 35 in which solids may react with or evolve gases or vapors. The bottoms of both the annulus 58 and the annulus 33 are open to permit free gas passage. The lower portion of annulus 58 and the conical closure i3d of the annulus 35 define a throat 35 for permitting escape of gases 9. from the reaction zones 33 and 35 into heat eX- change zone 40.

Optionally, suitable means for measuring the temperatures prevalent in the annular reaction zone 35 may be provided, and as shown, a temperature responsive device I4 may be suitably positioned to indicate reaction temperatures. Where it is desired to introduce vgases or vapor into the lower heat exchange zone |35 or into the interior of the cylindrical annulus 33, such gases or vapors may be suitably introduced by way of an inlet pipe 31. For some reactions, such as gasification of chars from non-coking coals, superheated steam or gases may be introduced into the reaction zone 35 as shown in Figure 12, by passing the vapors through a preheating device 6I located in the combustion chamber 24. When operating in this manner gases or vapors are introduced into inlet pipe 31 and are preheated preferably in a coil or annular jacket 6| mounted on the walls of combustion chamber 24, and are thence passed into the vessel 55. As shown in Figure 12a, the inlet pipe 31, in entering the vessel 56 is packed in a packing gland |11 by a rammed packing |18.

An alternative arrangement of apparatus to secure transfer of heat from the evolved gases` and vapors in the upper heat exchange zone 40 may be secured, as more particularly shown in Figure 7, by passing the incoming gases or vapors going into the lower heat exchange zone |35 through an inlet pipe 82 communicating with a source of gaseous reactants, and through a heat exchanger 54 positioned in the upper heat exchange zone 40, and` thence into the lower cylindrical annulus 36.

For some reactions, particularly the production of oil from oil bearing shales or high volatile noncoking coals, it may be desirable to recirculate a portion of the xed gases evolved from the upper heat exchange zone 40 into the lower heat exchange zone |35. As shown more particularly in Figure 8, this may be accomplished by passing the evolved gases or vapors through a suitable condensing device 65, a recirculating pipe |36, and a regulating valve I 31, to return the gases through the inlet pipe 31. By this means, a large quantity of carrier gas can be passed through the reaction apparatus in direct contact with the solid reactants to provide for more rapid transfer of heat and removal of evolved products as well as to repress formation of fixed gases.

In some multiple-stage reactions, for example in the successive distillation and. gasification of oil-bearing shales or non-coking coals, an intermediate cylindrical annulus |38 as shown in Figure 9 serves to permit the Withdrawal of intermediately-formed gases or vapors. In Figure 9, the upper cylindrical annulus 58 and the lower cylindrical annulus 36 are shortened to provide space in the vessel 56 for a similarly aligned intermediate cylindrical annulus |38. The intermediate annulus |38 (Figure 9) is spaced apart from the vessel 56 to define an intermediate reaction zone |55, and is open at the .bottom and spaced apart from a lower conical closure |34 to form a throat 34 for collecting evolved gases in the intermediate heat exchange zone |59. C'apping the intermediate cylindrical annulus |38 is a conical closure |58 which is connected to and provides a seat for a vertical vent pipe |51 passing upwardly through the upper heat exchange zone 40 and thence out of the vessel 55.

Associated with the elongated vessel 56 are novel heating means for supplying necessary endothermic heatto carry out the lreactio'r'is taking' place in the annular reaction zones 33, 35, and |55. As shown in Figure 3, such means may take the form of a combustion chamber having an outer casing |39 associated with a recuperator having an outer casing I6 for recovering 'heat from combustion gases, an exhaust fan |43, a fresh air duct 27 or alternately l5, and suitable adjustable means including .a valve |46 for recirculating a proportion of flue gases or p. o. c. `(products of combustion) to the combustion chamber as a tempering medium for controlling ame temperatures in the combustion zone 24 heating the vessel 55.

The combustion chamber outer casing |39 (Figures l, 2, 3 and 4) has a suitable base structure 1| and bottom closure |10 mounted therein. embracing the vessel 56 in a gas-tight sliding t. The top of the casing |39 has a. cap |40 embracing the upper portion of the vessel 56 in gas-tight Isealing engagement therewith. The casing I 39 is provided with an insulating refractory lining 51 through which extend a series of tangential burner ports 20, 2|, and 22 shown in detail in Figure 14. The tangential burner ports 20, 2|, and 22 are mounted in the outer casing |39 at different levels and direct burning fuel into the combustion zone 24 around the vessel 56. .A series of vertically ranging gas passage ducts I9 identifled by ducts A, B, C, D, E, F, G, H, I, J, K and L of Figure 14a are formed in the lining 51 and supply a preheated mixture of air and recirculated products of combustion p. o. c.) to tangential burner ports 20, 2|, and 22. In Figures 14a and lab, an arrangement of the tangential burner ports at two levels is indicated. In Figure 14a which represents a cross section through baille 53 at C-C in Figure 1, an arrangement of twelve vertical ducts VI 9 is indicated by clock-wise lettering from A to L. Such ducts are suitable for ring a medium sized combustion furnace. In a larger furnace a plurality of ducts would be provided to supply preheated air and products of combustion at different levels as the furnace increases in height, having about the same distribution at each level as that indicated in Figure 14h. Ducts I9 may be of any suitable shape and size to provide for required gas-now. Referring to Figure 3, the refractory insulating material 51 outlining the combustion zone 24 within the outer casing |39, is preferably made of light-weight insulating refractory key brick but suitable plastic insulating refractories that can be cast in place may be used. A gas passage manifold I1 'is formed in the lining 51 near the upper end thereof and provides a common source of supply for the ducts I9. Each duct I9 has an adjustable gas meteringvalve I8 which may be manually controlled as shown. Preheated air and p. o. c. mixture is supplied to the manifold I1 from the recuperator by a horizontally ranging inlet duct :$0 connecting the recuperator. and the manifold In the combustion zone 24 (Figure 3) a flame guard 23 extends from the bottom closure |10 or from the top of the refractory bottom lining upwardly toward'burner ports 2| and embraces the vessel 56 to protect it from excessive local heating. A horizontally ranging deflecting baille v53 is located in the upper portion of the combustion zone 24 below a discharge ue 25 to cause-combulstiin gases to travel completely around the vesse 5 A flue 25 in the casing I8| connects the 'upper portion of the combustion zone 24 above the bafiie 53 with the recuperator and serves to conduct combustion gases from the combustion zone 24 to the recuperator as shown in Figures 1, 2, 3 or 4.

The recuperator comprises an outer casing I6 mounted upon a base |62 forming a bottom closure suitably supported by means not shown, and a cap |6| forming an upper closure` The outer casing I6 is provided with a suitable insulating refractory lining |63 to minimize heat losses. vertically disposed in the casing I6 is a suitable tube bundle |66 supported by an upper tube sheet |61 and a lower tube sheet |68- (Figure 3) Suitable horizontal delecting bailes |42 are disposed inside the casing |6 about the tube bundle |66 to providefor an elongated gas passage traveling about and through the` tube bundle |66` The productsof combustion issuing from the combustion zone 24. through the ue 25 enter the recuperator below the upper tube sheet |61 and pass downwardly about the tube bundle |66 (Figure 3). They are removed from the recuperator through aflue 26,*after giving up their heat and are thence passed through an exhaust fan |43 into a stack juncture casing. |69. A lower header |65 is formed inthelcwer portion of the casing |6- and is adapted to distribute incoming air and-p. o. c. through the interior of the tube bundle |66. An upper header |64 is formed by the upper tube sheet |61 and: passes fresh air and recirculated products oicombustion into the inlet duct |60. The stack Y.iurictiire casingv |69, uponl which is mounted the stacliZ, is provided with a stack valve |45. The casina |69 also has. a valve |46 through which 2licontrolled proportion of products of combustion caniberecirculated to the system. Connecting the fresh. air inlet 2'l1andthe stack juncture |69 is a; juncture Zaior admixing recirculated flue gases.withireshcombustion air. Connecting the recuperatorlower header |65 and the juncture 21a isa duct 28t through which fresh air and' a controlled. proportion of combustion products may be sent through thel tube bundle of the recunerator.

Optionally, suitable means for introducing air intoathesystem is through inlet duct l forming aijllncton with duct 26 in advance of exhaust fan |435 Fresh air introduced at this point serves to coolithe fanblades. The fresh air and p. o. c. mixture handled by the fan is circulated back through the system through duct 28, and: part is; discarded to the stack 52- by regulation of Values-, |45. and |46.

Qptionally, suitable means@ are provided 'for' removing; additional Waste heat from the stack gaitrlrliconcurrently. drying and-preheating-the -so'lidgieedmaterial to .the vessel' 56. As show-n in Eigrure 4, suchc means comprise an annular gas cundueting jacket' 5 surrounding the upper portion of the. elongated vesselY 56 projecting from the cap,` l40iand adapted'to receive iiue gases from thegmodied stack A52. Engaging the upper porti'anothe jacket H''is asuitable-ue H6 adapted to remove the flue gases issuing from the annular jacket` H6. Associated with the flue ||61 is an auxiliary, combustion chamber adapted to providev additional heat. tothe combustion gases for drying. the solid feed material as next to be described.

Surmounting the elongatedovessel (Figure 4) inthid modified formofthe apparatusvr is a drying lchamber Il?! adaptedY to provide intimate Contact: between the solid1feed material and-flue gases. The flue llt` conducts gases from the jacket-|; and the auxiliary. combustion chamberf` LH? into theV drying chamber H4 at a controlled temperature indicated by teinperature're sponsive element H3. Horizontally disposed in 'ie drying chamber` H4 are a plurality of in-v verted metallic deecting angles |54 shown in detail in Figure 4a. The angles |54 are adapted to provide gas passages for the flue gases through fine-size solid feed material, and the spent gases leave through duct lili.

Optionally, if the solid material being treated is of close-graded size through Which gases will flow with only moderate pressure drop, by closing valve E63 and opening valve 7S, the heating gases are deflected from the bottom of the metallic dellecting angles |64 (Figure e) are forced to leave the system by passage through the broken solid material. This system of operation provides more contact surface and the heat is transrerred very eiiiciently. If desired, moist carbonaceous materials may be previously dried with high-pressure saturated steam before entering the system,

In the operation oi the heatin system or device associated with and forming a part of the reaction apparatus, fuel from gas header 5| Figure 4) is burned at the burners 26, 2 i and 22 in controlled amounts. The highiy heated products of combustion ascend and swirl about the vessel 56. They are then directed past the horiaontally ranging baille 53 through the ilue 25 into the recuperator outer casing I6. In the recuperator casing h6 the products of combustion pass downwardly in indirect countercurrent heat exchange relationship with incoming tempered air and o. c., being directed through the recuperator in an elongated path by the bailies |42, and give up a substantial portion of theirsensible heat. Issuing from the recuperator near the lower portion thereof, the partially cooled products of combustion pass by way of the flue 26 through the fan |143 into, respectively, the stack 52 and the fresh air duct 2 in accordance with the arrangement of the gas-now regulating valves |45 and |46. Fresh air or other source of oxygen for combustion enters through the air duct 2, is mixed with a pre-determined quantity of combustion products at the juncture Zla, and the diluted or tempered air then passes through the flue 28 back through the recuperator and into the combustion chamber manifold il. Optionally, fresh air may be introduced into the system through port l5 in duct 2,6 just in front of the fan as previously described; From the manifold Il' the tempered and partially preheated air passes downwardly through the metering valves I8 into the preheating ducts I9 and vthence to the burners 20, 2|, and 22, in suitably metered amounts. As shown, tL e preheating ducts |9 are in indirect countercurrent heat exchange relationship with the combustion zone 24 and the contained upwardly-moving products of combustion. By this arrangement and correlation of parts, a very desirable uniformly-controlled heating is secured for the elongated vessel 56 and the heating is carried out with very high thermal eiciency.

In operating the preheating and heat interchange devices for drying, roasting, or further abstracting` heat from the products of combustion issuing from the stack 52, or duct |92, the products of combustion pass from the stack 52 into the heat exchange jacket i {iandV give a portion of their heat to the reactants in the preheating zone 6. Thereupon, the partially cooled products of combustion pass through the ue H6, .are -optionallymixed with additional products of combustion generated in the auxiliary combustion chamber and thence are passed into the preheater or dryer i4. Through 'the interstices formed in the solid material bed by the members |54, the combined products of combustion give up their heat to the solid materials and suitably preheat and dry the feed material passing to the preheating zone 86 from the hopper 30.

Optionally another form of the heating system is illustrated in Figures 16, 16a and 16h. The combustion system in casing |39 is the same as that previously described but the recuperator is omitted and replaced by a specially built fan for recirculation of highly heated products of combustion. The fan |85 is mounted on a platform |98 supported by brackets |97 and connected to the shell casing |39. It is constructed of material adapted to withstand high temperatures and is insulated by a suitable insulating layer |94. A plurality of hollow blades |69 are mounted on a hollow shaft |88 extending into the fan casing 200. The hollow shaft |88 is carried by suitable outboard bearings |95 which are placed away from the heat on a suitable mounting. The shaft extends into an air junction box |86 and is driven by pulley |96, connected to a suitable prime mover (not shown) In the operation of this optional heating system or device associated with and forming a part of the reaction apparatus (Figure 16), fuel is burned at the tangential burners 26, 2|, and 22 in controlled amounts. The highly heated products of combustion ascend and swirl about the vessel 56 and are directed past the horizontal baie 53 through the flue 25 partly into the recirculating fan |65 and partly into the duct |92. The fan picks up a predetermined volume of products of combustion for return to the system through manifold I1, and also takes fresh air into the system for admixture with products of combustion. Fresh air, regulated by valve |81, is introduced into or drawn through air metering box |86 and passes through the hollow shaft |88 into the hollow fan blades |90, where it emerges through ports |89, preferably located on the trailing edge of the blades, and mixes with products of combustion. The fresh cooling air traveling at high speed through the hollow shaft and blades cools the metal and allows the fan to operate in the envelope of highly heated products of combustion. The discarded products of combustion passing through duct |92 enter a countercurrent heat exchange device |49, where they give up the major portion of their heat to gases or vapors used in the reactions carried out in the reaction vessel 56. The gases or vapors are introduced into the heat exchange device |49 through port |19, and they leave through port |80. Optionally the discarded products of combustion may be used for predrying or roasting solids as previously described and illustrated in Figure 4.

VProcess for distillation in single annulus In the operation of the apparatus for distillation of carbonaceous materials when employing a single elongated heat exchange device 58 within the housing 56 illustrated in Figures 5 and 6 mounted in the setting of Figure 4, solid feed material, such as lignite, non-coking coal, or oilshale, is suitably fed to the hopper 30 and passed downwardly through the preheater |54 and valve 3| into a further preheating zone 80 surrounding the outlet 4| and the upper portion of the extended housing 56 surrounded by the annular 14 jacket ||5. Tli'e the solid materials reach a temperature between 2-12 degrees F. and 500 degrees F. degrees C. and 260 degrees C.) taking up heat from evolved gases and from p. o. c. circulating in the jacket H5. The solids then pass downwardly by gravity into the annular reaction zone 33 defined by the vessel 56 and the concentric heat exchange device 58. As the solid materials pass downwardly through the annular reaction zone 33, reaction is initiated, and distillation proceeds to the desired point indicated by the temperature responsive elements 9, I0, and I4. 'Ihe evolved gases and vapors are suitably vented through ports 60 of Figure 6, or annular vents |32 of Figure 5, from the annular reaction zone 33 into the heat exchange zone 40, whereupon they reverse their direction of flow and-proceed upwardly in countercurrent heat exchange relationship to the descending solids in the annular reaction zone 33 creating a Venturi effect which aids the flow of gases .through orices 60. The spent solid materials such as char or spent shale continue downwardly to the solids discharging device 48 of Figure 4, or optionally to the valve 48a of Figure 2, or to the water seal device 50 (Figure 4) froml which they are removed by the drag conveyor 50a or the screw peratures than those cited above can be used but:

they will decompose more tar and oil vapors to; fixed gases approximately in proportion to the change in absolute temperature.

The evolved gases and vapors issuing from the vent pipe 4| are suitably treated in accordance with their source or composition to render them most suitable for their intended purposes. For

example, in the case of shale distillation for the production of oil and fixed gas, they are conducted into a fractional condensing device which may take the form of a bubble column 66 as shown in Figure 4. In this column 66, equipped with bubble caps |2I, the heavier oily substances produced are condensed, and the lighter fractions are conveyed through the pipe |25 into a condenser |26 for the separation of the more volatile condensible substances. From the condenser |26, the light fractions are collected in a receiver |28. In the bubble column 66, suitable vents are placed at spaced positions along the column to remove intermediate fractions, and as shown, these vents may take the form of a plurality of valved outlets |20, |22, and |23. If desired, reflux condensate may be admitted near the upper portion of the column at the inlet |24 and steam may be admitted near the base of the column through the inlet 203 to balance the slight additional heat as required. Heavy condensate may be removed from the condenser 66 at the base thereof and collected in the receiver 204.

Proces-s for distillation in double cumulus In the operation of the apparatus provided with two superposed annular heat exchange devices' in accordance with a preferred embodiment of the invention for distillation of non-ecking carbonaceous materials as illustrated in Figures 15j 4v and` 8; solid preheated materials, preferably size-graded and containing a minimum of fine sizes, pass downwardly as previously described through the first annular reaction zone 33, and are raised in temperature close to'that of initial thermal decomposition. When treating noncoking coals, the temperature of initial decomposition is 650 degrees F. to 750 degrees F. (or 340 degrees C. to 4001 degrees C.) Therefore in practical operation, the combustion and preheating systems are adjusted to produce a. developed temperature of about 700 degrees F. as indicated by temperature responsive element i9 placed near the center of the lower part of the reaction zone 33. The vertical positioning of throat 34-is designed to meet these conditions, but for all practical purposes, throat 34 is located about twothirds the height of the combustion chamber 24. Water vapor or initial products of thermaly decomposition forming in the reaction zonev33pass concurrently with the solid material and pass into the heat exchange zone #.6 through the throat 34. The solid materials now preheated to about 700 degrees F. pass downwardly by gravity through the annular reaction zone 35 dened: by the lower heat exchange device 36 and the elongated vessel 55. As the solid materials pass downwardly through this reaction Zone 35, they increase in temperature as indicated by temperature responsive elements 9 and I4 located about in the center of the reaction zone outlined by annulus 36 and reaction vessel 56. Low temperature distillation of the volatile hydrocarbons from coal'takes place between '750 degrees F. and 1200 degrees F. (400 degrees C. to 650 degrees CJ, and, when the external combustion system is suitably regulated to produce a temperature of about 1200 degrees F. (650 degrees C!) as indicated by temperature responsive element (lll), the maximum yields of primary low temperature tars are obtained. On the otherV hand;if it is desired to obtain more xed hydrocarbon-gases at the expense of lower tar or oil yields, the combustion chamber 24fis advanced intemperature to the desired point to yield the kind; and quality of products wanted. As the solid reactants pass downwardly through reaction zone 35, evolved gases and vapors or reactant gases or vapors pass countercurrently to the solids-'whereby heat is transferred to the upper solid materials. Heat transfer by thisinechanism may` be; aided by introducing carrier gases, recirculated distillation gases, steam; orf-other vaporousmaterials through the lower inlet pipe 3'1 -suitably-posi tioned in the heat transfer zonelllS. These-car,- rier gases pass upwardly through reaction zone 35extracting heat from the downcoming solids and from the lower wall of reaction yvessel 55; and transfer the heat to material higher up in zone 35. Thus the solid materials discharged from vessel 55 have onlyy a relatively lowtemperature in comparison to the maximum temperature obtained in the reaction zone. Evolved gases and vapors emerging from zone i0 leave thesystem through vent pipe :il-and are condensedas prel viously described. y

Optionally when distilling oil-shale-with two superposed annular heat exchange devicesY in accordance with a preferred embodiment of the invention illustrated in Figure 4, thesystem is operated in the samemanneras thatipreviously described for non-colring coal, lcut'the temperatures inside the lower reaction zone 3.5; are carried somewhat lower than whendistillingvvcoal..

t has been found that it is only necessaryto 16 heat'oil-bearing shales to about 700 degrees F. to 950 degrees F. (370 degrees C. to 500 degreesvC.) in order to extract the optimum quantity of potentiai condensable oil. The combustion system temperature or the rate of movement of the shale through the system is adjusted to producethe above temperature conditions inside the reaction zone 35 as indicated by the temperature responsive element ld. Optionally, greater yields of lxed hydrocarbon gases can be obtainedA at the expense of lower oil yields by advancing the temperature of reaction zone 35 as indicated by temperature responsive element I4 or by the temperature responsive element I located in combustion chamber 24.

As an example of test results obtained.y in the operation of the double annulus system for distillation of oil-bearing shale, the following experimental data were obtained during test in a small pilot plant similar to Figure 4:

Shale charging rate, pounds per hour 347 Spent shale discharging rate, pounds per hour 266 Oil distiled from shale, pounds per hour 59.7 Air introduced as carrier gas at inlet 3l,

cu. ft./hr 300 Distillation gas recirculated, through 31,

cu. ft./hr 723 Net yield of gas from system, cu. ft./hr. 505 Heat required for distillation, B. t. u./pound of shale 685 Potential heat in gas made, B; t. u./pound of shale 780 Temperature, bottom of combustion chamber-at point l F 1785 Temperature, middle-of combustion chamber at point 2 F 1490 Temperature, top of combustion chamber atpoint 3 F 1180 Temperature of p. o. c. out recuperatorV point 5 F 595 Temperature vapors leaving retort point l2 F 415 Temperature of shale in reaction zone point M F 855 Temperature of spent shale leaving reaction zone 35 F 640 Temperature of' shale leaving preheater SY F 130 Temperature of vapors at thoat Sli- F 580 Potential heat discarded in spent shale,

B. t. u.; lb. dry 1790 During the above test 26,377 pounds of shale wereV distilled and 4488 pounds of oil was, recovered over atest period of about 76 hours.

Process for distillation and gasification in multiple cumuli In the operation of the apparatus orv system provided with a plurality of. annular heat eX- change devices inaccordance with a preferred embodiment of the invention for distillation and completey gasication of solid non-coking carbonaceousrmaterials-vreference is; madef to Figure 9; Solid materialssnitablyfdriedloru preheated aspreviously` described ,inv the; discussion referring to.v Figure 4, .pass downwardly.' into. ref action. zone" 33 and; into` thel intermediate.-v reac.- tion zone i 5.5;A where f theyf undergo thermala de.- compositionv and distillation in accordance. with the mechanism. previously described; for: the doubleannulusfheat exchange system. For example, productsof. initial` decomposition. pass concurrently with 1thesolids :in reaction vzone 33; 

